1. Parameters of 2 nd SPL feasibility study A.M.Lombardi (reporting for the working group)

2. Contents  what has changed with respect to CDR1 [=conceptual design report]  frequency/ length /RF power/reliability and cost  energy and synergy  contributors to CDR2  planning and conclusions

3. CDR1 baseline  SPL-CDR1 design was based on re-using the de-commissioned LEP RF system (50 Klystrons at 352 MHz) with new SC cavities (beta < 1.0, Nb sputtered on Cu).  frequency fixed to 352 MHz,  final energy fixed to 2.2 GeV  Design tailored to the Neutrino Factory

4. SPL block diagram (CDR 1) SPL1 : 0 to 2.2 GeV in 650 meters

5. SPL beam characteristics (CDR 1) Ion species H-H-H-H- Kinetic energy 2.2GeV Mean current during the pulse 13mA Duty cycle 14% Mean beam power 4MW Pulse repetition rate 50Hz Pulse duration 2.8ms Bunch frequency (minimum distance between bunches) 352.2MHz Duty cycle during the pulse (nb. of bunches/nb. of buckets) 62 (5/8) % Number of protons per bunch 4.02 10 8 Normalized rms transverse emittances 0.4  mm mrad Longitudinal rms emittance 0.3  deg MeV Bunch length (at accumulator input) 0.5ns Energy spread (at accumulator input) 0.5MeV Energy jitter during the beam pulse < ± 0.2 MeV Energy jitter between pulses < ± 2 MeV

6. push for change  very good results on beta<1 700MHz bulk niobium SC cavities  global view on the costing of 352 vs. 700 MHz  2.2 GeV is a perfectly suited energy for a neutrino factory but not for a super beam A direct superbeam from a 2.2 GeV SPL does not appear to be the most attractive option for a future CERN neutrino experiment as it does not produce a significant advance on T2K. from SPSC-Villars04 recommendation

7. gradients at 700 MHz Last test performed in CryHoLab (July 04): 5-cells 700 MHz ß=0.65 Nb cavity A5-01 from CEA/Saclay and IPN-Orsay from Stephane Chel, HIPPI04, Frankfurt, sep04

8. gradients at 700 MHz Magnetic field limitation is a basic physics constraint, for Nb the hard limit is of the Order of 200 mT. Magnetic field limitation is a basic physics constraint, for Nb the hard limit is of the Order of 200 mT. Electric field limitation is set by the technological processes: material, treatments, handling and cleanness. The cavity shape has shown playing a crucial role while frequency has very little, if any, influence. Electric field limitation is set by the technological processes: material, treatments, handling and cleanness. The cavity shape has shown playing a crucial role while frequency has very little, if any, influence.

9. surface field doesn’t depend on frequency or beta Paolo Pierini, INFN MILANO, DRAFT

10. the ratio of surface electric/magnetic field to accelerating field increases rapidly at decreasing beta Paolo Pierini, INFN MILANO, DRAFT

11. the reduction of the beta of the cavity implies smaller inductive and capacitive volumes, thus leading to higher surface fields. Paolo Pierini, INFN MILANO, DRAFT

12. RF sources at 700 MHz  1 MW foreseen for 2007 in Cryolab (saclay)  4MW available from Thales (priced already at 1 MEuros)  there is a big jump (price, complexity) between a pulsed source (up tp 2 msec 50Hz, i.e. 10% duty cycle) and a CW one therefore power upgrades above 10 MW can be achieved only by increasing the final energy or the current

13. CDR2 baseline 3 families of cavity : beta =0.5,0.85,1.0 gradients : 15, 18, 30 MV/m 5, 6 and 7 cells per cavity

14. CDR2 baseline  Use cold (2K) quadrupoles in the cryomodules, independently aligned from the cavities (+: minimise cold/warm transitions and maximize real estate gradient, TESLA experience, large aperture).  Use cryomodules of maximum length (between 10 and 15 m), containing n cavities and (n+1) quadrupoles. Diagnostics, steering etc. between cryomodules.  The length of the cavities should be limited by fabrication and handling considerations. The proposed number of cells per cavity is therefore 5, 6 and 7 for the three sections.  2 MW max power /coupler  standardisation of the design after 2 GeV

15. CDR2 parameters Ion species H-H-H-H- Kinetic energy 3.5GeV Mean current during the pulse 40 (30 ?) mA Mean beam power 4MW Pulse repetition rate 50Hz Pulse duration 0.57 (0.76 ?) ms Bunch frequency 352.2MHz Duty cycle during the pulse 62 (5/8) % rms transverse emittances 0.4  mm mrad Longitudinal rms emittance 0.3  deg MeV

16. CDR2 block diagrams SPL2 : 0 to 3.5 GeV in 450 meters

17. why not 704 from the start ?  acceptance at 100kV 700 MHz too small  focusing from the RFQ too weak  Drift tube linac miniature dimensions  90 MeV is an optimal energy for the frequency jump

18. why not higher than 704 after few GeV? frequency jump needs longitudinal re- matching, i.e. lower synchronous phase Phase profile in SC LINAC at one single frequency Phase profile in SC LINAC with frequency jump

19.  1 frequency (MHz)  2 frequency (MHz)  3 frequency (MHz) Length (m) Nb of cavity 704704 410 (ESS) 410 (ESS)222 704704407219 704704704336129 7047041056339156 7041056382177 70410561056345154 10561056390189 105610561056362173 105610561408363187 105614081408369194 70410561408339168 preliminary optimisation by R. Duperrier, CEA Saclay

20. gradient/power/length/cost  total cost in a linac is generally proportional to length  reliability is increased if the system has less components and the components are standardized  the fact of having in house the 352 RF power source is out weighted by the gain in lenght and reliability.  352 bulk niobium cavity are not a good economical choice  we can’t reach above 2.2 GeV by re-using the LEP klystrons

21. energy and synergy  SPL must be a multi-user facility. Each user has a specific request on intensity/beam power/energy. Whilst intensity and beam power can be easily varied within the same machine (change of source current, change of duty cycle) the choice of the final energy must be such as to accommodate the max number of possible users. 

22. energy and synergy  potential users : Eurisol Eurisol betabeam betabeam superbeam superbeam neutrino factory neutrino factory CERN proton complex CERN proton complex 1-2 GeV 5 MW above 2 GeV 4 MW 200 MeV, above 2 GeV 3.5 GeV 4 MW

23. CDR2 contributors  The SPL study group at CERN  CEA Saclay and INFN Milano  HIPPI  ISTC collaboration with Russian laboratories and nuclear cities

24.  Stage 1: 3 MeV test place  development and test of linac equipment, beam characterization  Stage 2: Linac4 New linac replacing the present injector of the PS Booster (Linac2) New linac replacing the present injector of the PS Booster (Linac2) Front-end of the future SPL Front-end of the future SPL  improvement of the beams for physics (higher performance and easier operation for LHC, ISOLDE etc.)  Stage 3: SPL New injector for the PS, replacing the PS Booster New injector for the PS, replacing the PS Booster New physics experiments using a high proton flux New physics experiments using a high proton flux  improvement of the beams for physics and possibility of new experiments 3-stage approach

25. 3 MeV test place ready Linac4 approval SPL approval RF tests in SM 18 of prototype structures* for Linac4 CDR 2 Global planning

26. Conclusions CDR2 expected by the end of 2005 cointaining a feasibility study for a 3.5 GeV Superconducting H- LINAC based on 700 MHz cavities results of the evolution of CDR1 with contribution from CEA-Saclay, INFN Milano, HIPPI, ISTC....

27. Benefits of the SPL  Performance upgrade of LHC much higher beam brightness: necessary step towards an increased luminosity much higher beam brightness: necessary step towards an increased luminosity easier operation & higher reliability easier operation & higher reliability  Second Generation Radio-active Ion Beam Facility (EURISOL): proton beam power x 1000 proton beam power x 1000 flux of radio-active ions x 1000 flux of radio-active ions x 1000  Neutrino physics “super-beam (10 x beam power foreseen for the “CERN Neutrino to Gran Sasso” experiment) “super-beam (10 x beam power foreseen for the “CERN Neutrino to Gran Sasso” experiment) “beta-beam” “beta-beam” Neutrino factory Neutrino factory  High energy physics with fixed targets Easier operation, higher reliability & higher performance of the injector complex Easier operation, higher reliability & higher performance of the injector complex The beam from a single SPL can be time-shared and satisfy quasi-simultaneously all these needs

28. Three stages are planned:  Stage 1: 3 MeV test place  development and test of linac equipment, beam characterization Stages  Stage 2: Linac4 New linac replacing the present injector of the PS Booster (Linac2) New linac replacing the present injector of the PS Booster (Linac2) Front-end of the future SPL Front-end of the future SPL  improvement of the beams for physics (higher performance and easier operation for LHC, ISOLDE etc.)  Stage 3: SPL New injector for the PS, replacing the PS Booster New injector for the PS, replacing the PS Booster New physics experiments using a high proton flux New physics experiments using a high proton flux  improvement of the beams for physics and possibility of new experiments

29. SPL beam time structure (CDR 1) Fine time structure (within pulse) Macro time structure